This is an exploratory study and the information obtained may lead to new findings regarding the inflammatory and neurodegenerative mechanisms in the progression of PD and help to develop new drugs to halt the disease progression. The study simply involves a one time blood draw.
Heart disease can be detected in the hospital by Cardiac Magnetic Resonance (CMR)- a device that uses a large magnet. CMR is used to test how healthy the heart muscle is and how well the heart is pumping. We will test a new method to see how helpful it is to quickly get good pictures and if this is useful for testing the health of heart muscle in patients with heart disease.
Individuals with alpha-1 antitrypsin (AAT) deficiency (AAT blood level lower than 11 micro-moles) and emphysema will be invited to participate in this study. This study will determine the impact of IV Alpha-1 proteinase inhibitor (Alpha-1 MP) on the progression of emphysema in patients with AAT deficiency. A participant in this study would receive any one of the following three therapies: 1) Alpha-1 MP dosed at 60mg/Kg, 2) Alpha-1 MP dosed at 120mg/Kg, or 3) Placebo. Once a subject is enrolled into this study, he/she will be randomly selected to receive only one of the above three therapies. Neither the study investigators nor the participants will know the actual therapy being given to the participants. All the study participants will receive serial chest CT scans to determine if their emphysema progresses over the following 3 years. Participants will have the IV therapies given to them weekly, with some infusions given at MUSC and some at home. Safety and side effects of all therapies will be monitored.
RESTORE is a database of individuals who are interested in being contacted about future stroke research at the Medical University of South Carolina. Included in the database is health information and characteristics about the individual's health, stroke, and their recovery. The results of other stroke recovery studies the individual participates in at MUSC will also be in the database. The database and information included will lead to better and more targeted recruitment for stroke recovery projects.
Nicotine dependence remains a significant public health concern. Nicotine can affect brain neural oscillations. A magnetic field applied to the outside of the skull can produce electrical activity in the brain without significant pain or the need for anesthesia. In this proposal, we will build an individual brain signal-driven transcranial magnetic stimulation loop, and then test whether this stimulation loop can modulate neural oscillations and reduce cue-induced craving, including nicotine craving. This research will build an innovative brain stimulation method for neuroscientific research and develop a potential efficacy therapy for nicotine dependence as well other neuropsychiatric disorders.
The current investigation uses a brain-based technique, transcranial magnetic stimulation (TMS), which has helped to treat depression, to try to stimulate those brain regions understood to be essential to emotional experience and impaired in PTSD. In summary, the aim is to enhance emotion engagement and regulation and possibly uncover new brain-based interventions that could help ready the brain so an individual with PTSD could then fully engage and thus optimize emotion-focused psychotherapy.
The purpose of the MUSC Pulmonary Biorepository is to collect and store samples linked to medical and other information from individuals with pulmonary disease as well as healthy controls.
In combination with the clinical data and other approved research studies (that may recruit for and/or utilize samples of the biorepository) this sample repository will provide for uniform, longitudinal, complete and accurate data that can be organized and clinically correlated at the time of sample donation, with longitudinal testing possible as part of future study. Samples will be linked to each participant's unique ID, though will be deidentified and coded for use in future research and subsequent publications with pulmonary disease and control patients.
Reflexes are important parts of our movements. When reflexes are not working well, movements are clumsy or even impossible. After spinal cord injury, reflex responses may change. Researchers have found that people can learn to increase or decrease a reflex response with training. Recently, we have found that rats with spinal cord injuries can walk better after they are trained to change a spinal reflex. Thus, learning to change a reflex response may help people recover after a nervous system injury. In this study, we aim to examine whether learning to change a spinal reflex through operant conditioning training can improve movement function recovery after spinal cord injury.
Over many years, we have learnt that the brain's connections with the spinal cord change in response to injury or training. Because brain-spinal cord (i.e., corticospinal) pathways are very important in movement control, restoring function of these pathways could help to restore useful movement after spinal cord injury (SCI). In this project, we hypothesize that operant conditioning training of the muscle response to non-invasive transcranial magnetic stimulation can strengthen the functional connectivity of corticospinal pathways and thereby alleviate movement problems in people with chronic incomplete SCI. This study will require about 38 visits over the first 3 months, and another 4 visits over an additional 3 months. Each visit will take about an hour.
Spinal reflexes take important part in our movement. After spinal cord injury (SCI), reflexes often change. For many years, researchers and doctors have assumed that abnormally acting spinal reflexes lead to movement problems, without clear scientific evidence. For example, in people who suffer spasticity, a common problem after SCI, walking is disturbed, presumably because stretch reflexes (e.g., knee jerk reflex) and some other reflexes are not working well. Yet, which reflex is causing a problem in what way has not been well understood. Such understanding is very important in developing and applying effective therapies for improving gait recovery after SCI. Therefore, in this project, we are studying spinal stretch reflexes and other reflexes during walking, to understand how these reflexes contribute to spastic gait problems in people with chronic incomplete SCI. Successful completion of this project will result in better understanding of spastic gait problems, which in turn, will help us develop more effective therapy application and improve the quality of life in people after SCI.